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Lijuan Ruan Brookhaven National Laboratory Charles Gale McGill University

EW Probes and Heavy Quarks: lots of new calculations and new data!. Lijuan Ruan Brookhaven National Laboratory Charles Gale McGill University. EW Probes Quarkonium and Heavy Flavors.

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Lijuan Ruan Brookhaven National Laboratory Charles Gale McGill University

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  1. EW Probes and Heavy Quarks: lots of new calculations and new data! Lijuan Ruan Brookhaven National Laboratory Charles Gale McGill University

  2. EW Probes Quarkonium and Heavy Flavors • EW: Penetrating probes, biased towards high T, probe the entire history of the space-time dynamics, sensitive to transport coefficients • Heavy quarks: test of pQCD and of in-medium modification, initial state effects, energy loss (final state effect)

  3. P. Petreczky: Quarkonium state potential • Correlation function of the Polyakov loop related to the free energy of a static quark-antiquark pair: Lattice studies • New: the use of Wilson loop spectral functions allows for an extraction of the quark-antiquark potential Assume single-state dominance

  4. Potential systematically larger than F • but approaches as T increases • Implications for potential model • studies: • Real and Imaginary part will be calculated • consistently • Single-state dominance charmonium and 2S bottomonium states dissolves for T>245 MeV, 1S bottomonium states dissolves for T>450 MeV

  5. H. Ding: Dispersion relations • Relies on MEM to invert the mapping of the spectral function • Prediction of and dissociate at 1.46 Tc : new feature • Evaluation of the dispersion relation • Similar message for other channels • Effect on pheno models • Need to do studies over a range of temperatures

  6. In-medium Quarkonium R. Rapp: Transport theory Loss & gain terms Input & ingredients: • Primordial production cross-sections • CNM effects: Cronin, shadowing, absorption • Thermal fireball evolution • Includes gluon dissociation channel • Quarkonia binding energy determined from a screened • potential (WBS), or from a T=0 potential (SBS) • Allows for a survey of results from SPS, RHIC, and LHC

  7. PT spectrum at RHIC: contributions from supression, regen., and CNM absorption • PT spectrum at LHC: contributions from supression, regen., and CNM absorption. • Regeneration causes the low momentum bump • Consistency between new lattice results and SBS

  8. R. Sharma: High PT quarkonia and heavy flavors • Use NRQCD to calculate elementary production cross sections (short-scale part) • Non-perturbative (longer scale) components fitted to experiment (e.g. Tevatron data) • Consider CNM effects: • Shadowing, Cronin effect, initial state E loss • Quarkonia dissociate on a time • scale tdiss • Solve coupled rate equations tform No Cronin Physics is largely in the formation/dissociation times

  9. K. Tuchin: Gluon saturation effects on Charmonium in dA and AA • Multiple scattering effects in the nuclear medium (formation time) will make the production mechanism coherent. • Proto-charmonium interacts with the nucleus (dA): enhancement due to higher twist/mult scatterings • Use the MV model; calculate the dipole (cc)-nucleon cross-section RHIC, LHC; different y’s CNM from first principles. LHC prediction No qualitative agreement for AA

  10. S. Cao: Heavy quark evolution & flow • Include radiative E loss of heavy quark by extending the Langevin equation Respective effects of radiative & collisional E loss Check effect on light flavors

  11. Thermal Photons & Dileptons D. Teaney: Photons @ NLO • Photon yield=Photon-emission rates hydro • LO rates in QGP phase = AMY (2001) NLO: S. Caron-Huot (2010)

  12. Larger angle emission Conversion photons • Net correction to emission rate not • numerically important in region up to • k/T ~10 • Techniques developed here will have other • applications in FTFT

  13. R. Fries: Jet-Photon conversions Hard to observe, trigger on jet first LHC RHIC • NLO effects wash out signal, but it still shines • Background evaluations

  14. Low and Intermediate Mass Dileptons G. Vujanovic: Thermal dileptons with 3D viscous hydro • Use vector meson spectral densities consistent with analysis of NA60 data • Use viscous 3D hydro consistent with analysis of hadronic data • Investigated effect of viscous corrections to dilepton spectra and v2, including c E-loss v2: sensitive to viscosity corrections IMR spectrum and v2: sensitive to charm energy-loss

  15. The experimental results Outline: • Heavy flavor: D, B, and their decayed • e and  • Quarkonia: J/,  and their excited states • Controlled Probes: W, Z, and  • Thermal di-leptons and photons: , e+e-, and +-

  16. The measurements presented at QM2012

  17. Surprising results at QM2012 PHENIX: McGlinchey, Nouicer, Rosati, Sakaguchi, Wysocki • PHENIX: RAA(be) < RAA (ce) • at pT=1-5 GeV/c in 200 GeV Au+Au • PHENIX: RdAu(’) < RdAu(J/) by a factor of 5 in most central d+Au • CMS: At 1.6<|y|<2.4, 3<pT<30 GeV, (2S) less suppressed than J/ in central Pb+Pb, not confirmed by ALICE with 2.5<|y|<4, 3<pT<8 GeV. CMS: Mironov, Moon, Roland; ALICE: Arnaldi, Safarik, Scomparin

  18. Open heavy flavor measurements in p+p collisions STAR: Dong, Tlusty, Xie; ALICE: Valle • Charm cross section follows Nbin scaling from p+p to Au+Au collisions • Expect to get 60 ccbar and 2 bbbar pairs in central Pb+Pb collisions at 2.76 TeV • Expect to get 15 ccbar and 0.1 bbbar pairs in central Au+Au collisions at 200 GeV • Coalescence from bbbar to  is negligible at RHIC.

  19. Open heavy flavor results in A+A • Significant charmed hadron, B hadron suppression observed. RAA(D)~RAA() RAA(BJ/) • D meson flows (High precision measurements of electron, muon RAA and v2 also reported by ALICE, ATLAS, and STAR) • Need more precise measurements to study color charge and/or flavor dependence of energy loss STAR: Dong, Tlusty, Xie ALICE: Caffarri, Grelli, Safarik, Valle; CMS: Mironov, Jo

  20. J/ results in p+p STAR: arXiv: 1208.2736, Trzeciak, Xie • The J/ production at pT>3 GeV/c, follows xT scaling in p+p collisions. • B feed-down contribution:<20% at pT<10 GeV/c, more significant at higher pT

  21. J/ results in 200 GeVCu+Au PHENIX: Hollis, Rosati, Sakaguchi In Cu+Au collisions, RAA(Au-going) > RAA(Cu-going), qualitatively described by CNM but not quantitatively. Additional suppression suggests hot, dense medium effect

  22. J/ results in A+A: centrality dependence ALICE: Arnaldi, Arsene, Safarik, Scomparin PHENIX: PRC84(2001)054912 • Npart dependence of J/ RAA: less suppression at LHC compared to at RHIC in central collisions • interplay between CNM, color screening and ccbar recombination • consistent with more significant contribution from ccbar recombination at LHC energies

  23. J/ results in A+A: pT dependence PHENIX: PRL98(2007)232301 STAR: arXiv: 1208.2736, Trzeciak, Xie CMS: Mironov, Moon, Roland ALICE: Arnaldi, Safarik, Scomparin, Yang • J/ RAA decreases from low to high pT at LHC. • J/ RAA increases from low to high pT at RHIC. • At high pT, J/ more suppressed at LHC. • Hint for possible J/ flow at pT=3 GeV/c at LHC. • Models incorporating color screening and • recombination can consistently describe the J/ • suppression pattern and flow measurements.

  24.  result in p+p, dAu collisions STAR Preliminary STAR: Trzeciak, Xie ; PHENIX: HP2012; CMS: PRD83(2011)112004 •  cross section consistent with NLO calculations. • Rapidity dependence of  nuclear modification in d+Au observed. • Different  state measured in CMS.

  25.  results in A+A STAR: Dong, Trzeciak, Xie CMS: arXiv: 1208.2826, Mironov, Rangel, Roland • (1s) suppression magnitude consistent with excited states suppression. • (2S) strongly suppressed, (3S) completely melted. • Now is the perfect time to study color screening features of hot, dense • medium in light of RHIC and LHC precise quarkonium measurements.

  26. Electro-weak probes CMS: Benhabib, Cassagnac, Roland, Stephans ATLAS: Dolejsi, Grabowska-Bold, Steinberg, Wosiek W, Z and high energy  production in heavy ion collisions: consistent with number of binary scaling. Initial nuclear wave function effect is not significant wrt. uncertainties PHENIX: arXiv:1205.5759, Tserruya

  27. RHIC di-lepton results at last QM PHENIX PRC 81 (2010) 034911 Enhancement factor in 0.15<Mee<0.75 Gev/c2 • The discrepancy is in 0-20% central Au+Au collisions. The 0-20% HBD results will • be important to clarify the discrepancy experimentally.

  28. Energy dependence of di-electron spectra 20-40% STAR: Dong, Geurts, Huang, Huck PHENIX: Atomssa, Tserruya • PHENIX HBD results at 200 GeV : consistent with previous publication in 20-92% centrality. • STAR results: systematically study the di-electron continuum from 19.6, 39, 62.4 and 200 • GeV. Note: enhancement factor (EF) depends on the reference: • using cocktail as a reference, which includes charm contribution, the EF has no • centrality dependence from STAR experiment. • using Npart as a reference, there is centrality dependence.

  29. Direct photon spectra and elliptic flow v2 • Low pT direct photon elliptic flow measurement could provide direct constraints on QGP dynamics (η/s, T, t0…). • Excess of direct photon yield over p+p: Teff=221 ± 19 ± 19 MeV in 0-20% Au+Au; substantial positive v2 observed at pT<4 GeV/c. • Excess of direct photon yield over p+p at pT<4 GeV/c: Teff=304 ± 51 MeV in 0-40% Pb+Pb. • Di-lepton v2 versus pT & Mll: probe the properties of the medium from hadron-gas dominated to QGP dominated. (R. Chatterjee, D. K. Srivastava, U. Heinz, C. Gale, PRC75(2007)054909) ALICE: Wilde, Safarik PHENIX, arXiv: 1105.4126 PHENIX: PRL104 (2010)132301 pT (GeV/c)

  30. Di-electron v2 at 200 GeV Au+Au • Cocktail simulation is consistent with the measured di-electron v2 at Mee<1.1 GeV/c2. • Need a factor of two more data to be sensitive to hardon gas and QGP contribution, in addition to independent measurements to disentangle ccbar correlation contribution R. Chatterjee, D. K.Srivastava, U. Heinz, C. Gale, PRC75(2007)054909) STAR: Cui, Geurts, Huang

  31. A tool to study Chiral Symmetry Restoration • Abroadened spectral function describes di-lepton enhancement from SPS at 17.3 GeV to top RHIC energy from STAR. • Chiral condensate depends on temperature and total baryon density. • The total baryon density does not change significantly from 17.3 to 200 GeV. Spectral function from measurements consistently be broadened. • With future precise spectra and v2 measurements over a broad beam energy range, di-lepton will serve as an ideal tool to study Chiral Symmetry Restoration. Large enhancement in 0-20% central Au+Au at 200 GeV would imply new mechanisms. NA60, Eur.Phys.J.C59(2009)607 STAR: Cui, Dong, Geurts, Huang, Huck CERES: Eur.Phys.J.C41(2005)475

  32. Summary At RHIC and LHC, strongly interacting Quark-Gluon Plasma created: Heavy flavor: charmed hadrons and B-meson strongly suppressed in A+A Collisions; charmed hadrons flow. Quarkonia: the centrality and pT dependence of J/ suppression pattern at RHIC and LHC can be interpreted as the interplay of two key ingredients: recombination and color screening; (2S) strongly suppressed, (3S) completely melted. We are in the era to study color screening features of hot, dense medium in light of RHIC and LHC precise quarkonium measurements. Electro-weak probes: abroadened spectra function describes STAR’s 19.6, 62, and 200 GeV data and SPS data consistently. Precise di-lepton measurements over a broad beam energy scan at RHIC, LHC and FAIR provides a unique opportunity to study Chiral Symmetry Restoration.

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